Improved CRISPR genome editing using small highly active and specific engineered RNA-guided nucleases.

Streptococcus pyogenes (Spy) Cas9 has potential as a component of gene therapeutics for incurable diseases. One of its limitations is its large size, which impedes its formulation and delivery in therapeutic applications. Smaller Cas9s are an alternative, but lack robust activity or specificity and frequently recognize longer PAMs. Here, we investigated four uncharacterized, smaller Cas9s and found three employing a "GG" dinucleotide PAM similar to SpyCas9. Protein engineering generated synthetic RNA-guided nucleases (sRGNs) with editing efficiencies and specificities exceeding even SpyCas9 in vitro and in human cell lines on disease-relevant targets. sRGN mRNA lipid nanoparticles displayed manufacturing advantages and high in vivo editing efficiency in the mouse liver. Finally, sRGNs, but not SpyCas9, could be packaged into all-in-one AAV particles with a gRNA and effected robust in vivo editing of non-human primate (NHP) retina photoreceptors. Human gene therapy efforts are expected to benefit from these improved alternatives to existing CRISPR nucleases.

Directed Evolution of Orthogonal Pyrrolysyl-tRNA Synthetases in Escherichia coli for the Genetic Encoding of Noncanonical Amino Acids.

The directed evolution of orthogonal aminoacyl-tRNA synthetases (aaRS) for the genetic encoding of noncanonical amino acids (ncAA) has paved the way for the site-specific incorporation of >170 functionally diverse ncAAs into proteins in a large number of organisms [1, 2]. Here, we describe the directed evolution of orthogonal pyrrolysyl-tRNA synthetase (PylRS) mutants with new amino acid selectivities from libraries using a two-step selection protocol based on chloramphenicol and barnase reporter systems. Although this protocol focuses on the evolution of PylRS variants, this procedure can be universally employed to evolve orthogonal aaRS.

Modulation of the endogenous omega-3 fatty acid and oxylipin profile in vivo-A comparison of the fat-1 transgenic mouse with C57BL/6 wildtype mice on an omega-3 fatty acid enriched diet.

Dietary intervention and genetic fat-1 mice are two models for the investigation of effects associated with omega-3 polyunsaturated fatty acids (n3-PUFA). In order to assess their power to modulate the fatty acid and oxylipin pattern, we thoroughly compared fat-1 and wild-type C57BL/6 mice on a sunflower oil diet with wild-type mice on the same diet enriched with 1% EPA and 1% DHA for 0, 7, 14, 30 and 45 days. Feeding led after 14-30 days to a high steady state of n3-PUFA in all tissues at the expense of n6-PUFAs. Levels of n3-PUFA achieved by feeding were higher compared to fat-1 mice, particularly for EPA (max. 1.7% in whole blood of fat-1 vs. 7.8% following feeding). Changes in PUFAs were reflected in most oxylipins in plasma, brain and colon: Compared to wild-type mice on a standard diet, arachidonic acid metabolites were overall decreased while EPA and DHA oxylipins increased with feeding more than in fat-1 mice. In plasma of n3-PUFA fed animals, EPA and DHA metabolites from the lipoxygenase and cytochrome P450 pathways dominated over ARA derived counterparts.Fat-1 mice show n3-PUFA level which can be reached by dietary interventions, supporting the applicability of this model in n3-PUFA research. However, for specific questions, e.g. the role of EPA derived mediators or concentration dependent effects of (individual) PUFA, feeding studies are necessary.

EPR Distance Measurements in Native Proteins with Genetically Encoded Spin Labels.

The genetic encoding of nitroxide amino acids in combination with electron paramagnetic resonance (EPR) distance measurements enables precise structural studies of native proteins, i.e. without the need for mutations to create unique reactive sites for chemical labeling and thus with minimal structural perturbation. We here report on in vitro DEER measurements in native E. coli thioredoxin (TRX) that establish the nitroxide amino acid SLK-1 as a spectroscopic probe that reports distances and conformational flexibilities in the enzyme with nonmutated catalytic centers that are not accessible by the use of the traditional methanethiosulfonate spin label (MTSSL). We generated a rotamer library for SLK-1 that in combination with molecular dynamics (MD) simulation enables predictions of distance distributions between two SLK-1 labels incorporated into a target protein. Toward a routine use of SLK-1 for EPR distance measurements in proteins and the advancement of the approach to intracellular environments, we study the stability of SLK-1 in E. coli cultures and lysates and establish guidelines for protein expression and purification that offer maximal nitroxide stability. These advancements and insights provide new perspectives for facile structural studies of native, endogenous proteins by EPR distance measurements.

Genetic code expansion as a tool to study regulatory processes of transcription.

The expansion of the genetic code with non-canonical amino acids (ncAA) enables the chemical and biophysical properties of proteins to be tailored, inside cells, with a previously unattainable level of precision. A wide range of ncAA with functions not found in canonical amino acids have been genetically encoded in recent years and have delivered insights into biological processes that would be difficult to access with traditional approaches of molecular biology. A major field for the development and application of novel ncAA-functions has been transcription and its regulation. This is particularly attractive, since advanced DNA sequencing- and proteomics-techniques continue to deliver vast information on these processes on a global level, but complementing methodologies to study them on a detailed, molecular level and in living cells have been comparably scarce. In a growing number of studies, genetic code expansion has now been applied to precisely control the chemical properties of transcription factors, RNA polymerases and histones, and this has enabled new insights into their interactions, conformational changes, cellular localizations and the functional roles of posttranslational modifications.

Programmable and highly resolved in vitro detection of 5-methylcytosine by TALEs.

Gene expression is extensively regulated by specific patterns of genomic 5-methylcytosine (mC), but the ability to directly detect this modification at user-defined genomic loci is limited. One reason is the lack of molecules that discriminate between mC and cytosine (C) and at the same time provide inherent, programmable sequence-selectivity. Programmable transcription-activator-like effectors (TALEs) have been observed to exhibit mC-sensitivity in vivo, but to only a limited extent in vitro. We report an mC-detection assay based on TALE control of DNA replication that displays unexpectedly strong mC-discrimination ability in vitro. The status and level of mC modification at single positions in oligonucleotides can be determined unambiguously by this assay, independently of the overall target sequence. Moreover, discrimination is reliably observed for positions bound by N-terminal and central regions of TALEs. This indicates the wide scope and robustness of the approach for highly resolved mC detection and enabled the detection of a single mC in a large, eukaryotic genome.

Structural basis of furan-amino acid recognition by a polyspecific aminoacyl-tRNA-synthetase and its genetic encoding in human cells.

The site-selective introduction of photo-crosslinking groups into proteins enables the discovery and mapping of weak and/or transient protein interactions with high spatiotemporal resolution, both in vitro and in vivo. We report the genetic encoding of a furan-based, photo-crosslinking amino acid in human cells; it can be activated with red light, thus offering high penetration depths in biological samples. This is achieved by activation of the amino acid and charging to its cognate tRNA by a pyrrolysyl-tRNA-synthetase (PylRS) mutant with broad polyspecificity. To gain insights into the recognition of this amino acid and to provide a rationale for its polyspecificity, we solved three crystal structures of the PylRS mutant: in its apo-form, in complex with adenosine 5'-(ß,γ-imido)triphosphate (AMP-PNP) and in complex with the AMP ester of the furan amino acid. These structures provide clues for the observed polyspecificity and represent a promising starting point for the engineering of PylRS mutants with further increased substrate scope.

A genetically encoded spin label for electron paramagnetic resonance distance measurements.

We report the genetic encoding of a noncanonical, spin-labeled amino acid in Escherichia coli. This enables the intracellular biosynthesis of spin-labeled proteins and obviates the need for any chemical labeling step usually required for protein electron paramagnetic resonance (EPR) studies. The amino acid can be introduced at multiple, user-defined sites of a protein and is stable in E. coli even for prolonged expression times. It can report intramolecular distance distributions in proteins by double-electron electron resonance measurements. Moreover, the signal of spin-labeled protein can be selectively detected in cells. This provides elegant new perspectives for in-cell EPR studies of endogenous proteins.

Red-light-controlled protein-RNA crosslinking with a genetically encoded furan.

Well red: A protein-RNA crosslinker has been genetically encoded that can be controlled with red light, thus offering high penetration depths in biological materials. This should enable the discovery and mapping of transient protein-RNA interactions and enable the design of peptide- and protein-based drugs for RNA-targeted photodynamic therapy.

A need for speed: genetic encoding of rapid cycloaddition chemistries for protein labelling in living cells.

Rapid reactions: Several reactants for strain-promoted cycloaddition reactions have been genetically encoded as the side chains of noncanonical amino acids. This results in decisive improvements for the fluorescent labelling of intracellular proteins such as quantitative turnover, completion of labelling reactions within minutes, fluorogenic effects and even partial orthogonality for multicolour labelling.